System having a power tool and an AC/DC hand portable wet/dry vacuum that share a battery pack

ABSTRACT

A tool set with a battery pack, a power tool and a utility vacuum. The power tool includes a receptacle assembly for detachably coupling the battery pack to the power tool. The utility vacuum has a canister, a powerhead assembly, which is coupled to the canister and has a fan, a motor for providing rotary power to the fan, and a power supply for distributing electrical power to the motor, and a shut-off device that prevents the fan from drawing a liquid into the fan inlet when a volume of the liquid in the canister exceeds a predetermined volume. The power supply includes a receptacle assembly for detachably receiving the battery pack. The battery pack may be selectively coupled to either of the power tool and the utility vacuum to provide a source of electrical power thereto. A method for operating a battery-powered tool set is also provided.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of U.S. patent application Ser. No. 10/640,267 filed on Aug. 13, 2003, which claims the benefit of U.S. Provisional Application No. 60/425,371, filed on Nov. 12, 2002.

FIELD

The present disclosure generally relates to vacuum appliances and more particularly to an AC/DC powered hand-portable wet/dry vacuum having improved convenience and performance.

BACKGROUND

Vacuum appliances that are capable of picking up both wet and dry materials are commonly known as wet/dry vacuums. Such wet/dry vacuums are well known in the art and are commercially available in a variety of sizes and configurations. Recent consumer trends have placed significant cost pressures the commercially available wet/dry vacuums and as such, many manufacturers are presently producing low-end, relatively small capacity low-cost units and/or high-end, relatively high capacity high-cost professional grade units.

The low-end, low-cost units are frequently employed by professional users, such as installers, service technicians and tradespeople in residential construction. These professionals are commonly required to clean their job site prior to leaving for their next job and as such, they frequently prefer the smaller size and portability that are typical of these units. These units, however, are known to have several drawbacks.

One such drawback relates to convenience of the known wet/dry vacuums and in particular the relatively long amount of time that is necessary for their set-up, the frequency with which the hose becomes disconnected during transport or use and the frequency with which the attachments are lost. Due to the relative bulk of the known wet/dry vacuums and their attachments, the professional user frequently makes a dedicated trip to transport the wet/dry vacuum to or from a jobsite.

Another drawback relates to the availability of electrical power on a given jobsite. In new residential construction, it is relatively common to encounter a jobsite where electrical power from an electrical utility is unavailable. In some situations, it may be possible to acquire electrical power from a nearby location (e.g., a neighbor) through long, heavy extension cords. Alternatively, a portable generator is required. The inconvenience of heavy extension cords and the expense and inconvenience of a portable generator is highly undesirable to a professional user, particularly considering that the professional user frequently uses the wet/dry vacuum for less than 10 minutes on a given jobsite.

Yet another drawback concerns the filter system of the known wet/dry vacuums. These filter systems typically employ a disposable filter that is fixedly attached to the lid of the vacuum or some other supporting structure that fits around and covers the fan. When clogged, the disposable filter can severely limit the flow of air through the fan, which significantly impairs the ability of the wet/dry vacuum to pick up debris. Often times, however, a replacement filter is not available to the professional user so that the wet/dry vacuum is simply used at reduced efficiency. Other drawbacks of the known filtering systems include the inconvenience of servicing a filter, which usually entails disassembly of the wet/dry vacuum so as to expose the jobsite to the contents of the canister, and insufficient filtering that results in the discharge of dust from the wet/dry vacuum when the wet/dry vacuum is turned on.

Accordingly, there remains a need in the art for a wet/dry vacuum having improved convenience and performance.

SUMMARY

In one form, the present disclosure provides a tool set that includes a battery pack, a power tool and a utility vacuum. The power tool has a receptacle assembly for detachably receiving the battery pack. The a utility vacuum has a canister, a powerhead assembly and a shut-off device. The powerhead assembly is coupled to the canister and has a fan, a motor for providing rotary power to the fan, and a power supply for distributing electrical power to the motor. The fan includes a fan inlet. The shut-off device is associated with the powerhead assembly and configured to prevent the fan from drawing a liquid into the fan inlet when a volume of the liquid in the canister exceeds a predetermined volume. The power supply includes a receptacle assembly for detachably receiving the battery pack. The battery pack may be selectively coupled to either of the power tool and the utility vacuum to provide a source of electrical power thereto.

In another form, the present disclosure provides a tool set with a battery pack, a power tool and a utility vacuum. The power tool includes a receptacle assembly for detachably coupling the battery pack to the power tool. The utility vacuum having a canister, a powerhead assembly and a shut-off device. The powerhead assembly is coupled to the canister and has a fan, a motor for providing rotary power to the fan, and a power supply for distributing electrical power to the motor. The shut-off device is associated with the powerhead assembly and configured to prevent the fan from drawing a liquid into the fan inlet when a volume of the liquid in the canister exceeds a predetermined volume. The power supply includes a receptacle assembly for detachably receiving the battery pack. The battery pack may be selectively coupled to either of the power tool and the utility vacuum to provide a source of electrical power thereto.

In another form, the present disclosure provides a method for operating a battery-powered tool set that includes a utility vacuum and a power tool. The method includes uncoupling the battery pack from the power tool; and coupling the battery pack to the utility vacuum to thereby provide the utility vacuum with a cordless source of electrical power.

Further areas of applicability of the present disclosure will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the disclosure, are intended for purposes of illustration only and are not intended to limit the scope of the disclosure.

DRAWINGS

Additional advantages and features of the present disclosure will become apparent from the subsequent description and the appended claims, taken in conjunction with the accompanying drawings, wherein:

FIG. 1 is a perspective view of a wet/dry utility vacuum constructed in accordance with the teachings of the present disclosure;

FIG. 2 is an exploded view of the wet/dry vacuum of FIG. 1;

FIG. 3 is a schematic illustration of a portion of the wet/dry vacuum of FIG. 1 illustrating the controller and charging circuit in detail;

FIG. 4 is a sectional view of a portion of the wet/dry vacuum of FIG. 1 illustrating the receptacle assembly in greater detail;

FIG. 5 is a schematic view of the wet/dry vacuum of FIG. 1 illustrating the flow path when the wet/dry vacuum is used in the vacuuming mode;

FIG. 6 is a schematic view of the wet/dry vacuum of FIG. 1 illustrating the flow path when the wet/dry vacuum is used in the blowing mode;

FIG. 7 is a sectional view of a second wet/dry vacuum constructed in accordance with the teachings of the present disclosure;

FIG. 8 is a sectional view of a third wet/dry vacuum constructed in accordance with the teachings of the present disclosure;

FIG. 9 is a sectional view similar to FIG. 8 but illustrating the powerhead assembly in a raised condition and the canister assembly removed from the housing;

FIG. 10 is a sectional view of a fourth wet/dry vacuum constructed in accordance with the teachings of the present disclosure;

FIG. 11 is a sectional view similar to FIG. 10 but illustrating the canister assembly removed from the housing;

FIG. 12 is a sectional view of a fifth wet/dry vacuum constructed in accordance with the teachings of the present disclosure;

FIG. 13 is a sectional view similar to FIG. 12 but illustrating the secondary filter in a removed condition;

FIG. 14 is a perspective view of a sixth wet/dry vacuum constructed in accordance with the teachings of the present disclosure;

FIG. 14A is a front elevation view of the wet/dry vacuum of FIG. 14;

FIG. 15 is a longitudinal section view of the wet/dry vacuum of FIG. 14;

FIG. 16 is an enlarged portion of FIG. 15 illustrating the cooling inlet aperture in greater detail;

FIG. 17 is an enlarged portion of FIG. 15 illustrating the cooling outlet aperture in greater detail;

FIG. 18 is a schematic view of a portion of the wet/dry vacuum of FIG. 14 illustrating the controller in greater detail;

FIG. 19 is a perspective view of the wet/dry vacuum of FIG. 14 illustrating the lid in a lowered condition and the battery pack exploded from the battery pack enclosure;

FIG. 20 is a schematic view of a portion of the wet/dry vacuum of 14 illustrating the power supply in greater detail;

FIG. 21 is a schematic view of a portion of the wet/dry vacuum of FIG. 14 illustrating the switching device in greater detail;

FIG. 21A is a schematic view similar to that of FIG. 21 but illustrating an alternately constructed controller;

FIG. 22 is an enlarged portion of FIG. 15 illustrating the primary filter in greater detail;

FIG. 23 is a top plan view of the primary filter;

FIG. 24 is a side elevation view of a portion of the primary filter illustrating the configuration of the retaining tab in greater detail;

FIG. 25 is a bottom view of a portion of the wet/dry vacuum of FIG. 14 illustrating the housing of the powerhead assembly in greater detail;

FIG. 26 is a side elevation view of a portion of the housing of the powerhead assembly illustrating one of the retaining slots in greater detail;

FIG. 27 is a top plan view of a portion of the wet/dry vacuum of FIG. 14 illustrating the coupling end of the hose assembly in greater detail;

FIG. 28 is a rear elevation view of the wet/dry vacuum of FIG. 14 illustrating the hose assembly in a first stored condition;

FIG. 29 is a view similar to that of FIG. 28 but illustrating the hose assembly in a second stored condition;

FIG. 30 is a top view of a portion of the wet/dry vacuum illustrating the electrical cord in a stored condition; and

FIG. 31 is a perspective view of a tool set constructed in accordance with the teachings of the present disclosure.

DETAILED DESCRIPTION

With reference to FIG. 1 of the drawings, a hand-portable wet/dry vacuum constructed in accordance with the teachings of the present disclosure is generally indicated by reference numeral 10. In the particular example illustrated, the vacuum 10 is shown to include a powerhead assembly 12, a canister assembly 14, a filter system 16, a hose assembly 18, a plurality of conventional hose-end attachments 20, a shoulder strap 22, a first electrical cord 24, a second electrical cord 26 and a battery pack 28.

With additional reference to FIG. 2, the powerhead assembly 12 may be removably attached to the canister assembly 14 and includes a housing 40, a motor 42, a fan 44 and a controller 46. The housing 40 defines an inlet port 50, an outlet port 52, a handle 54 and a central cavity 56 into which the motor 42, fan 44 and controller 46 are housed. The inlet port 50 may be routed to the canister assembly 14 on a first side of the filter system 16 while the outlet port 52 may be routed to the canister assembly 14 on a second side of the filter system 16. Air flowing into the inlet port 50 flows into the canister assembly 14 and through the filter system 16 prior to being directed out of the outlet port 52. The motor 42 and the fan 44, which is coupled for rotation with the output shaft (not shown) of the motor 42, cooperate to blow air out of the outlet port 52 to thereby draw air into the powerhead assembly 12 via the inlet port 50.

In FIG. 3, the controller 46 is illustrated to preferably include a first electrical socket 60, a second electrical socket 62, a receptacle assembly 64, a power supply 66, a power switch 68 and a charger circuit 70. Each of the first and second electrical sockets 60 and 62 and the receptacle assembly 64 are electrically coupled to the power supply 66 and configured to conduct electrical power thereto as will be described in detail, below. The power supply 66 is electrically coupled to the motor 42 and the power switch 68 in a conventional manner to permit the user to selectively enable or disable the flow of electrical power to the motor 42.

The first electrical cord 24 preferrably includes a conventional pronged plug end 74, which is configured to be electrically coupled to a conventional electrical outlet 76, and a conventional first connector-end 78 that is configured to be electrically coupled to the first electrical socket 60. Accordingly, the first electrical cord 24 permits the user of the wet/dry vacuum 10 to couple the power supply 66 to a source of alternating current (AC) power.

The second electrical cord 26 preferably includes a conventional cylindrical plug-end 84, which is configured to be electrically coupled to a conventional cigarette lighter socket 86 of an automotive vehicle, and a conventional second connector-end 88, which is configured to be electrically coupled to the second electrical socket 62. Accordingly, the second electrical cord 26 permits the user to couple the power supply 66 to a source of direct current (DC) power, such as to the electrical system and battery of an automotive vehicle.

In the example of FIGS. 3 and 4, the receptacle assembly 64 is illustrated as being flexibly connected to the housing 40 via a flexible gasket 90. Preferably, the gasket 90 is made of a flexible resilient material, such as rubber or another elastomer. The receptacle assembly 64 includes a receptacle housing 94, which is configured to receive the battery pack 28, and a connector 96 that is floatingly disposed in the receptacle housing 94 to minimize the shock received by a battery pack 28 if the wet/dry vacuum 10 is dropped. The connector 96 has a plurality of terminals (not shown) with a configuration that contacts the associated terminals (not shown) of the battery pack 28. Preferably, the battery pack 28, terminals, receptacle housing 94 and connector 96 are configured in the manner disclosed in U.S. Pat. No. 5,144,217, the disclosure of which is hereby incorporated by reference as if fully set forth herein. Accordingly, the receptacle assembly 64 permits the user to couple the power supply 66 to the battery pack 28 so that the wet/dry vacuum 10 may be operated without either of the first and second electrical cords 24 and 26 being coupled thereto, as when, for example, a source of AC or DC electrical power is unavailable or inconvenient to access. Also preferably, the power supply 66 is compatible with battery packs having various different voltages (e.g., 18 v, 14 v, 12 v, and/or 9.6 v) in a manner that is well known in the art. Those skilled in the art will appreciate that any manual or automatic means may be employed to select the source of power for the wet/dry vacuum 10. For example, a conventional rotary switch may be provided to permit the user to manually select between AC power, DC power (from the second power cord 26) and a battery pack 28. Alternatively, an automatic switch (comprising transistors or any other suitable electrical device) may be employed such that the power supply 66 will “look” for one power type, such as AC power, first, and should it not be available, look for “DC” power from the second power cord 26 next and thereafter from the battery pack 28.

In FIG. 3, the charger circuit 70 is coupled to the power supply 66 and the receptacle assembly 64 in a manner that is well known in the art. The charger circuit 70 allows for the charging of battery packs having different voltages, as is well known in the art. An example of a suitable charger circuit is disclosed in U.S. Pat. No. 6,427,070, the disclosure of which is incorporated by reference as if fully set forth herein.

Accordingly, a user can charge a battery pack 28, when the motor 42 is not running, by placing the battery pack 28 in the receptacle assembly 64 such that the terminals of the connector 96 electrically engage the associated terminals of the battery pack 28 and providing the wet/dry vacuum 10 with another source of electrical power via one of the first and second electrical cords 24 and 26. Once charged, the battery pack 28 may then be removed from the receptacle assembly 64 and employed to power another device, such as the heavy-duty audio equipment of U.S. Pat. No. 6,427,070 or the cordless drill/driver of U.S. Pat. No. 6,431,289.

Returning to FIG. 2, the canister assembly 14 preferably includes a canister 100 and a latching system 102 that releasably secures the canister 100 to the powerhead assembly 12. The particular canister illustrated has a capacity of about two gallons, but those skilled in the art will appreciate that the canister 100 may in the alternative have a capacity that is larger or smaller.

The filter system 16 may be completely attached to the powerhead assembly 12 but in the particular example provided, is carried canister 100 and includes a plenum 110 that is releasably attachable to the powerhead assembly 12, a float ball 112, a primary filter 114 and a secondary filter 116. The plenum 110 may have a hollow, cage-like construction that permits air to flow therethrough. The plenum 110 serves to retain and support the primary filter 114 as well as retain and guide the float ball 112 in a generally vertical orientation. The float ball 112 rises automatically within the plenum 110 to close off the filter system 16 from the fan 44 (which cuts off the flow of air through the powerhead assembly 12) when liquid in the canister 100 reaches a predetermined level.

The primary filter 114 may include a filter structure (not specifically shown), Which is formed from a rigid plastic material, and a fabric filter material (not specifically shown) that completely surrounds at least side of the filter structure. The fabric filter material is preferably formed of a washable filter material so as to permit the primary filter 114 to be washed when loaded with dust or dirt, rather than disposed of and replaced. As those skilled in the art will appreciate, however, the primary filter 114 may be made of any suitable filtering material, including an open-cell foam or a conventional filter paper (in which case the primary filter 114 would be disposable). Optionally, a pre-filter structure (not shown) may also be employed. Suitable prefilter structures include wire mesh or plastic screens, or open-cell foam which serve to collect dust and dirt (e.g., drywall dust) before the dust-carrying airflow contacts the primary filter 114.

The secondary filter 116, which is optional and in the particular example provided carried by the powerhead assembly 12, is disposed upstream of the primary filter 114 and is of a generally finer mesh or porosity so as to collect relatively small dust particles before they are expelled through the outlet port 52. The secondary filter 116 is preferably removable from the filter system 16 without disassembling the canister assembly from the powerhead assembly 12. In the example provided, an access port 130 is formed in the housing 40 between the primary filter 114 and the fan 44. When the secondary filter 116 is received into the access port 130, a gasketed door 132 that may be hingedly coupled to the housing 40 is closed to seal the access port 130 and ensure that air flowing to the fan 44 encounters the primary filter 114 and then the secondary filter 116. The purpose of the secondary filter 116 is to provide very fine filtering of the air passing through the wet/dry vacuum 10 so that dirt and dust are not expelled from the outlet port 52 when the wet/dry vacuum 10 is operated. Preferably, the wet/dry vacuum 10 may also be used without the secondary filter 116 when the expelling of relatively fine dust from the outlet port 52 is not an issue.

With reference to FIGS. 1 and 2, the hose assembly 18 is preferably a flexible vacuum hose which is fixedly coupled to the inlet port 50. Also preferably, the hose assembly 18 is at least partially retractable into the inlet port 50 so as to provide a convenient means for storage of the hose assembly 18. Alternatively, the hose assembly 18 may be removably friction fitted on a selective basis to the inlet port 50 (for vacuuming) or the outlet port 52 (for blowing).

The distal end of the hose assembly 18 may be friction-fittable to any of the hose-end attachments 20. Such hose-end attachments 20 are well known in the art and as such, a detailed discussion of their construction and use need not be provided herein. To prevent the hose-end attachments 20 from being lost, a plurality of receiving slots 140 may be formed into the housing 40 and/or canister 100. The receiving slots 140 may be constructed to frictionally engage an associated one of the hose-end attachments 20. When not in use, each hose-end attachment 20 may be coupled to the housing 40 and/or canister 100 via its associated receiving slot 140.

The shoulder strap 22, which is optional, is coupled to the powerhead assembly 12 and permits the user of the wet/dry vacuum 10 to wear the unit over their shoulder so that their hands may be used for other tasks, including transporting other equipment or manipulating the hose assembly 18 when the wet/dry vacuum 10 is in use. In the particular embodiment illustrated, the shoulder strap 22 is coupled to the handle 54, which is integrally formed with the housing 40.

As noted above, the hose assembly 18 is preferably fixedly coupled to the inlet port 50 and as such, is not connectable to the outlet port 52 so that the wet/dry vacuum 10 can be used as a blower in a conventional manner (i.e., by connecting the hose assembly 18 to the outlet port 52). As best shown in FIGS. 1, 5 and 6, the wet/dry vacuum 10 may include a valve assembly 150 that selectively controls the flow of air to the fan 44. More specifically, the valve assembly 150 may be a two-position four-way valve that includes an actuator 154 and a valve element 156. In the particular embodiment illustrated, the actuator 154 is a rotary style actuator that is movable between a first setting 160 and a second setting 162. The valve element 156 is coupled for rotation with the actuator 154 such that when the actuator 154 is positioned in the first setting 160, air is drawn from the inlet port 50 through the filter system 16 and into the fan 44 in the manner described above. When the actuator 154 is positioned in the second setting 162, the valve element 156 moves (e.g., rotates in the example provided) to cause the outlet port 52 to be in fluid communication with the inlet side of the filter system 16 and the inlet port 50 to be in fluid communication with the discharge side of the fan 44.

As those skilled in the art will appreciate, various components of the wet/dry vacuum 10, such as the motor 42, the fan 44 and the primary filter 114, may be constructed and/or arranged in a manner that is well known in the art. Such components, constructions and arrangements are illustrated and discussed, for example, in U.S. Pat. No. 6,363,574, which is hereby incorporated by reference as if fully set forth herein.

With reference to FIG. 7, a second wet/dry vacuum constructed in accordance with the teachings of the present disclosure is generally indicated by reference numeral 10 a. Although schematically illustrated, the wet/dry vacuum 10 a is generally similar to the wet/dry vacuum 10 of FIG. 1 except that the filter system 16 a is integrated with the canister assembly 14 a. More specifically, the plenum 110 a is coupled to the canister 100 a and the primary filter 114 a completely shrouds the plenum 110 a. When the powerhead assembly 12 a is coupled to the canister assembly 14 a, a gasket 170 is compressed between the primary filter 114 a and the powerhead assembly 12 a to thereby sealingly engage the primary filter 114 a to the powerhead assembly 12 a.

When the canister 100 a is to be emptied, the powerhead assembly 12 a is unlatched from the canister 100 a, the primary filter 114 a is removed from the canister 100 a and the canister 100 a may be overturned to empty its contents. Like the primary filter 114, the primary filter 114 a is preferably at least partially constructed from a washable and re-usable filtering material to thereby eliminate the need for replacement filters. This configuration is advantageous in that all of the dirty components are located together and remain in an upright condition when they are being removed. In contrast to the known wet/dry vacuums wherein the filter system is coupled to the powerhead, dust and other debris remain contained within the canister 100 a when the powerhead assembly 12 a is removed. Furthermore, removal and/or replacement of the primary filter 114 a is quick and efficient, as no fasteners are employed to fix the position of the primary filter 114 a relative to the powerhead assembly 12 a.

With reference to FIGS. 8 and 9, another wet/dry vacuum constructed in accordance with the teachings of the present disclosure is generally indicated by reference numeral 10 b. Although schematically illustrated, the wet/dry vacuum 10 b is generally similar to the wet/dry vacuum 10 a of FIG. 7 except that the powerhead assembly 12 b is pivotally (via a hinge 179, for example) attached to a housing 180 that houses the canister assembly 14 b.

When the canister assembly 14 b is to removed from or inserted into the housing 180, the powerhead assembly 12 b is pivoted upwardly as shown in FIG. 9. Once the canister assembly 14 b is seated within the housing 180, the powerhead assembly 12 b is pivoted downwardly so that a gasket 182 that is carried by the powerhead assembly 12 b sealingly engages the canister 100 b.

Those skilled in the art will appreciate that the gasket 182 may alternatively be carried by the canister 100 b. A conventional latch mechanism 183 may be employed to secure the powerhead assembly 12 b to the canister assembly 14 b.

With reference to FIGS. 10 and 11, a fourth wet/dry vacuum constructed in accordance with the teachings of the present disclosure is generally indicated by reference numeral 10 c. Although schematically illustrated, the wet/dry vacuum 10 c is generally similar to the wet/dry vacuum 10 b of FIGS. 8 and 9 except that the powerhead assembly 12 c is fixedly attached attached to the housing 180 c that houses the canister assembly 14 c. The canister assembly 14 c is therefore inserted to and removed from the housing 180 c by sliding the canister assembly 14 c into or out of the housing 180 c.

With reference to FIGS. 12 and 13, yet another wet/dry vacuum constructed in accordance with the teachings of the present disclosure is generally indicated by reference numeral 10 d. The wet/dry vacuum 10 d is generally similar to the wet/dry vacuum 10 c of FIGS. 10 and 11, except that a secondary filter 116 d is incorporated into the filter system 16 d. Like the secondary filter 116 shown in FIG. 5, the secondary filter 116 d may be located between the fan 44 and the primary filter 114 d and is relatively finer in porosity/mesh so that dirt and dust are not expelled from the outlet port 52 when the wet/dry vacuum 10 d is operated. Advantageously, the secondary filter 116 d may be removed and cleaned or replaced without removal of the canister assembly 14 d.

With reference to FIG. 14, a sixth vacuum constructed in accordance with the teachings of the present disclosure is generally indicated by reference numeral 10 e. The vacuum 10 e is shown to preferably include a powerhead assembly 12 e, a canister assembly 14 e, a filter system 16 e, a hose assembly 18 e, a plurality of conventional hose-end attachments 20 e, a shoulder strap 22 e, an electrical cord 24 e and a battery pack 28 e.

With additional reference to FIG. 15, the powerhead assembly 12 e may be removably attached to the canister assembly 14 e and may include a housing 40 e, a motor 42 e, a fan 44 e and a controller 46 e. The housing 40 e may define one or more of an inlet port 50 e, an outlet port 52 e, a handle 54 e and a central cavity 56 e into which the motor 42 e, fan 44 e and controller 46 e may be housed. The inlet port 50 e is routed into the canister assembly 14 e on a first side of the filter system 16 e while the outlet port 52 e routes air out of the powerhead assembly 12 e on a second side of the filter system 16 e. Air flowing into the inlet port 50 e may flow into the canister assembly 14 e and through the filter system 16 e prior to being directed out of the outlet port 52 e. The motor 42 e and the fan 44 e, which is coupled for rotation with the output shaft (not shown) of the motor 42 e, cooperate to preferably blow air out of the outlet port 52 e which thereby draws air into the canister assembly 14 e via the inlet port 50 e.

In the example provided, the housing 40 e may be configured to aid in the cooling of the motor 42 e during its operation. More specifically, the housing 40 e may be configured with one or more cooling inlet apertures 500 and one or more cooling outlet apertures 502, with both of the cooling inlet and outlet apertures 500 and 502 being in fluid communication with the central cavity 56 e as will be described in greater detail, below. In the embodiment provided, a single cooling inlet aperture 500 and a single cooling outlet aperture 502 are employed. With additional reference to FIGS. 16 and 17, the cooling inlet aperture 500 is illustrated as being concentrically disposed about the inlet port 50 e to thereby disguise its location on the housing 40 e, but those skilled in the art will appreciate that the cooling inlet aperture(s) 500 may be located at various other locations on the housing 40 e. The cooling outlet aperture 502 may be located in the portion of the housing 40 e that defines the outlet port 52 e. In the example provided, the cooling outlet aperture 502 extends through a trailing portion 510 of a protrusion 512 that is formed on the wall 514 of the outlet port 52 e and oriented in a direction such that a longitudinal axis of the protrusion 512 is generally parallel to the flow of air through the outlet port 52 e.

The particular vacuum 10 e provided is configured such that during its operation, air flows through the outlet port 52 e to create a zone 520 of relatively low static pressure proximate the cooling outlet aperture 502, causing air to flow from the central cavity 56 e through the cooling outlet aperture 502 where it merges with the air flowing through the outlet port 52 e. The air departing from the central cavity 56 e likewise draws fresh air into the central cavity 56 e through the cooling inlet-aperture 500. The exchange of air in the central cavity 56 e permits the motor 42 e to reject relatively higher levels of heat. More specifically, the air flowing through the central cavity 56 e provides an air stream permits that flows against the motor 42 e to thereby permit the motor 42 e to reject heat therefrom with a convective heat transfer mechanism.

In FIG. 18, the controller 46 e is illustrated to preferably include a receptacle assembly 64 e, a power supply 66 e, a power switch 68 e and an optional charger circuit 70 e. The receptacle assembly 64 e is electrically coupled to the power supply 66 e and configured to conduct electrical power thereto as will be described in detail, below. The power supply 66 e is electrically coupled to the motor 42 e and the power switch 68 e to permit the user to selectively enable or disable the flow of electrical power to the motor 42 e.

The electrical cord 24 e may include a conventional pronged plug end 74 e, which is configured to be electrically coupled to a conventional electrical outlet 76 e, and an opposite end (not shown) which is electrically coupled in a conventional manner to the power supply 66 e. Accordingly, the electrical cord 24 e may permit the user of the wet/dry vacuum 10 e to couple the power supply 66 e to a source of alternating current (AC) power.

The receptacle assembly 64 e may be generally similar to the receptacle assembly 64 of FIGS. 3 and 4 and as such, need not be discussed in significant detail. In the example provided, the receptacle assembly 64 e is illustrated in FIG. 19 to be disposed in a battery enclosure 550 that is coupled to or integrally formed with the housing 40 e. A lid 552 may be hingedly coupled to the battery enclosure 550 and is movable between a closed position (FIG. 14), which substantially closes the battery enclosure 550, and an open position, which substantially clears the battery enclosure 550. An over-center camming latch mechanism 556 may be employed to selectively maintain the lid 552 in the closed position. An optional battery pack gasket 560 and leaf spring 562 may also be employed. The battery pack gasket 560 may be disposed between the battery pack 28 e and one or both of the receptacle assembly 64 e and the battery enclosure 550 (i.e., battery pack gaskets 560 in the latter example), while the leaf spring 562 may be attached to the lid 552 and positioned so as to push the battery pack 28 e into electrical contact with the receptacle assembly 64 e and sealing contact with the battery pack gasket 560 when the lid 552 is positioned in the closed position. The battery pack gasket 560 inhibits liquids from entering the receptacle assembly 64 e and the interior of the housing 40 e despite the presence of vent apertures 564 (FIG. 25) that extend through the battery enclosure 550 and/or lid 552.

The receptacle assembly 64 e permits the user to couple the power supply 66 e to the battery pack 28 e so that the wet/dry vacuum 10 e may be operated when, for example, a source of AC electrical power is unavailable or inconvenient to access. Also preferably, the power supply 66 e is compatible with battery packs having various different voltages (e.g., 18 v, 14 v, 12 v, and/or 9.6 v). Stated another way, the power supply 66 e is preferably configured such that a first battery pack having a first output voltage and a second battery pack having a second output voltage that is different than the first output voltage may be used interchangeably to power the power supply 66 e. In the particular example provided, the power supply 66 e includes an AC/DC converter 600 and a DC/DC converter 602 as shown in FIG. 20. The AC/DC converter 600 preferably has an electromagnetic interference suppression module 610, a rectifier 612 for rectifying alternating current power input thereto from the electrical cord 24 e, and a switching power supply 614 for pulse-modulating the rectified (i.e., direct current) power provided by the rectifier 612. The switching power supply 614 switches (i.e., turns on and off) to control its output to the motor 42 e. By controlling the duration of each of the “on” and “off” events, the switching power supply 614 is able to apply power of a desired voltage to the motor 42 e. A feedback loop 620 may optionally be included in the power supply 66 e for more accurate control of the voltage. Similarly, the DC/DC converter 602 may include a switching power supply 624 that is similar to the switching power supply 614 of the AC/DC converter 600 in that it switches (i.e., turns on and off) to control its output to the motor 42 e to thereby apply power of a desired voltage to the motor 42 e. Consequently, electrical power of a relatively identical voltage may be provided to the motor 42 e regardless of the voltage of the battery pack 28 e.

The power supply 66 e preferably includes a switch device 630 for automatically selecting the source of power for the wet/dry vacuum 10 e. With reference to FIG. 21, the switch device 630 is illustrated to be optionally integrated with the DC/DC converter 602 and may include, for example, an integrated circuit 640, first and second resistors 642 and 644, respectively, and a transistor 646. The integrated circuit 640 may be configured such that if it receives power from the AC/DC converter 600, the integrated circuit 640 will turn the transistor 646 “off” so that the power from the battery pack 28 e will not be transmitted to the motor 42 e. Accordingly, the switch device 630 may be configured so that the battery pack 28 e will power the vacuum 10 e unless the vacuum 10 e is coupled to a source of alternating current power in the manner described above.

With brief reference to FIG. 21A, an alternately constructed power supply 66 e is illustrated. The power supply 66 e differs from the power supply 66 e of FIG. 21 in that the switch device 630 is associated with the AC/DC converter 600. More specifically, the switch device 630 is illustrated as being a relay 630-1 with first and second contacts 630-2, 630-3, respectively, that are employed to control the flow of electricity. The relay 630-1 is illustrated in its normal condition wherein a lead 630-4 from the motor 42 e is electrically coupled to the first contact 630-2, which is in turn electrically coupled to the DC/DC converter 602 (via the power switch 68 e). The relay 630-1 remains in its normal condition unless the AC/DC converter 600 provides power (through the power switch 68 e in the example provided) to the relay 630-1. When the vacuum 10 e is coupled to a source of alternating current power and the power switch 68 e is switched on, the relay 630-1 causes the lead 630-4 from the motor 42 e to be electrically coupled to the second contact 630-3, which is in turn electrically coupled to the AC/DC converter 600 (via the power switch 68 e). Those skilled in the art will appreciate from this disclosure that the power supply, in its broader aspects; may be constructed somewhat differently and as such, the particular examples described and illustrated in this application are exemplary only and not intended to be limiting in any manner.

Returning to FIG. 18, the charger circuit 70 e may be coupled to the power supply 66 e and the receptacle assembly 64 e. The charger circuit 70 e allows for the charging of battery packs having different voltages, as is well known in the art. An example of a suitable charger circuit is disclosed in U.S. Pat. Nos. 6,427,070 and 6,496,688, the disclosures of which are hereby incorporated by reference as if fully set forth herein.

Accordingly, a user can charge a battery pack 28 e, when the power supply 66 e is coupled to a source of alternating current power by placing the battery pack 28 e in the receptacle assembly 64 e such that the terminals (not shown) of the connector (not shown) of the receptacle assembly 64 e electrically engage the associated terminals (not shown) of the battery pack 28 e. Once charged, the battery pack 28 e may then be employed to power the vacuum 10 e or removed from the receptacle assembly 64 e and employed to power another device, such as the heavy-duty audio equipment of U.S. Pat. No. 6,427,070 or the cordless drill/driver of U.S. Pat. No. 6,431,289.

With brief reference to FIG. 14A, the housing 40 e may be configured so as to define a recess 41 e into which the power switch 68 e is disposed. In the particular example provided, the power switch 68 e is a toggle switch.

Returning to FIG. 14, the canister assembly 14 e preferably includes a canister 100 e and an over-center cam latching system 102 e that employs a pair of over-center cam latches 700 to releasably secure the canister 100 e to the powerhead assembly 12 e. The particular canister 100 e illustrated has a capacity of about two gallons, but those skilled in the art will appreciate that the canister 100 e may in the alternative have a capacity that is larger or smaller. Preferably, the canister assembly 14 e also includes a reservoir emptying means 101 e that permits a liquid to be emptied from the interior of the canister 100 e without removing the powerhead assembly 12 e from the canister assembly 12 e. The reservoir emptying means 101 e may be a valve (not shown), such as a ball valve or gate valve. In the particular example provided, the reservoir empting means 101 e includes a threaded boss 101-1, a gasket 101-2 and a threaded cap 101-3. The threaded boss 101-1 extends outwardly from the canister 100 e and is threaded about at least a portion of its exterior surface. The threaded cap 101-3 includes an internal thread that is configured to threadably engage the threaded boss 101-1. The gasket 101-2, which is formed from a resilient, elastomeric material in the example provided, is disposed between the end of the threaded boss 101-1 and an interior surface of the threaded cap 101-3; the gasket 101-2 sealingly engages the end of the threaded boss 101-1 and the threaded cap 101-3 when the threaded cap 101-3 is tightened against the threaded boss 101-1.

In contrast to the filter system 16 of FIG. 1, the filter system 16 e may be configured to be carried entirely by the powerhead assembly 12 e as is shown in FIG. 15. The filter system 16 e includes a shut-off device 740, a primary filter 114 e and an optional secondary filter 116 e. In the example provided, the secondary filter 116 e may be a pad of fiberous material that is coupled to the fan inlet 742, but it could also be made of a mesh or screen material or omitted altogether depending upon the filtering capabilities of the primary filter 114 e. Also, the secondary filter 116 e may be coupled to the power head assembly 12 e at a point after (downstream) of the fan 44 e.

The shut-off device 740 is associated with the powerhead assembly 12 e and configured to prevent the fan 44 e from drawing a liquid into the fan inlet 742 when a volume of liquid in the canister assembly 14 e exceeds a predetermined volume. The shut-off device 740 may be configured in various ways and may, for example, prevent electrical power from being transmitted to the motor 42 e or close-off the fan inlet 742 in response to a volume of liquid in the canister assembly 14 e increasing above the predetermined volume. In the particular example provided, the shut-off device 740 includes a plenum 110 e and a float 112 e. The plenum 110 e may be a hollow, cage-like construction that permits air to flow therethrough and which serves to retain and guide the float 112 e along a generally vertical axis. The float 112 e, which is illustrated in the example provided as being a hollow sphere, is configured to rise automatically within the plenum 110 e to close off the fan inlet 742 e (to thereby halt the flow of air into the fan 44 e and through the powerhead assembly 12 e) when liquid in the canister 100 e reaches a predetermined level. Those skilled in the art will appreciate from this disclosure that the float 112 e may be configured with a shape that may not be spherical or even closed. For example, the float 112 e may have a generally cylindrical shape that is closed on a single end.

The primary filter 114 e may include a filter body 760, an internal support structure 762, a lower end cap 764 and an upper end cap 766. The filter body 760 may be formed from any appropriate filter material, including paper or fabric. In the particular example provided, however, the filter body is formed from a pleated material that is air and vapor permeable, but resistant to the infiltration or penetration of liquids therethrough so that the filter body 760 may be readily cleaned as through washing. Optionally, the material from which the filter body 760 is made is also hydrophobic and/or oleophobic so that the filter body 760 will not be wetted by water and/or oils that are drawn into the canister assembly 14 e. Our testing has shown that one particularly suitable material for the filter body 760 is comprised of a filter media support bonded to a porous expanded PTFE membrane, with one such suitable material being marketed as Gore Wet/Dry Filter Products manufactured by W. L. Gore & Associates, a Delaware Corporation having a place of business in Elkton, Md. Also optionally, the filter body 760 may be configured to provide HEPA (high efficiency particulate air) filtration or ULPA (ultra low penetration air) filtration.

The internal support structure 762 may be a cage-like structure that is disposed about the interior of the filter body 760 and fixedly coupled to one or both of the lower and upper end caps 764 and 766. The internal support structure 762 is configured to axially and radially support the filter body 760 during the operation of the vacuum 10 e to thereby prevent the filter body 760 from crushing or distorting in response to a pressure differential between the interior and exterior surfaces of the filter body 760.

The lower end cap 764 may be a plate-like structure that is formed from a rigid material and is sealingly bonded to a lower end of the filter body 760. Alternatively, the lower end cap 764 may be wholly or partially formed from the material from which the filter body 760 is manufactured.

The upper end cap 766 may be an annular flange that is sealingly bonded to an upper end of the filter body 760. With reference to FIGS. 15 and 22 through 24, the upper end cap 766 preferably includes a body 770 that defines a receiving aperture 772, which receives the plenum 110 etherethrough when the primary filter 114 e is coupled to the powerhead assembly 12 e, a seal engagement structure 774, which is illustrated as extending axially from the body 770 and oriented generally concentric with the receiving aperture 772, and a plurality of retaining tabs 776 that are circumferentially spaced about the perimeter of the body 770 and which extend radially outward therefrom.

The seal engagement structure 774 is sized to engage a corresponding filter gasket 780 that is formed from an elastomeric material and disposed about the fan inlet 742 adjacent a lower surface of the housing 40 e. In the particular embodiment illustrated, the filter gasket 780 is fixedly coupled to the housing 40 e, but could alternatively be fixedly coupled to the upper end cap 766 or removably coupled to either the housing 40 e or the upper end cap 766.

With additional reference to FIGS. 25 and 26, the retaining tabs 776 may be configured to matingly engage corresponding retaining slots 790 that are formed in the housing 40 e in an area proximate the fan inlet 742. In the particular example provided, the retaining tabs 776 are illustrated as having a generally flat upper surface 792, a tapered lower surface 794 and an engagement feature 796.

The retaining slots 790 may be formed in the inner surface 800 of a collar 802 that extends generally perpendicularly from the bottom surface of the housing 40 e concentric to the fan inlet 742. Each retaining slot 790 may be generally L-shaped, with a first portion 810, which is configured to axially receive a corresponding one of the retaining tabs 776, and a second portion 812 that extends around a portion of the circumference of the collar 802. The second portion 812 includes an engagement surface 814 that is configured to engage the lower surface 794 of a corresponding one of the retaining tabs 776. In the example provided, the engagement surface 814 is tapered and includes a notch-like retaining feature 816 that is configured to receive therein the engagement feature 796 of a corresponding one of the retaining tabs 776.

With reference to FIGS. 22, 23 and 26, when the primary filter 114 e is to be coupled to the housing 40 e, the primary filter 114 e is installed over the plenum 110 e and the retaining tabs 776 are each inserted to the first portion 810 of an associated retaining slot 790. The primary filter 114 e may then be rotated to move the retaining tabs 776 into the second portion 812 of the retaining slots 790. With sufficient rotation of the primary filter 114 e, the engagement features 796 of each of the retaining tabs 776 are coupled with an associated retaining feature 816 (i.e., received into an associated retaining feature 816 in the particular example provided) to thereby hinder opposite rotation of the primary filter 114 e so that the primary filter 114 e will not disengage the housing 40 e during the operation of the vacuum 10 e.

The tapered lower surface 794 on the retaining tabs 776 and the tapered engagement surface 814 cooperate when the primary filter 114 e is being rotated so as to translate the primary filter 114 e axially toward the housing 40 e. In this way, the seal engagement structure 774 is forced into sealing engagement with the filter gasket 780 to thereby inhibit the introduction of liquids into the fan 44 e from a point between the upper end cap 766 and the housing 40 e. The ability to seal the primary filter 114 e against the housing 40 e is of particular importance in those instances where a HEPA or ULPA filter material is employed for the filter body 760, since the filter gasket 780 also inhibits debris from infiltrating between the housing 40 e and the upper end cap 766.

In the particular example provided, both the second portion 812 of the retaining slots 790 and the tapered lower surfaces 794 of the retaining tabs 776 are tapered in a way that not only facilitates axial movement of the primary filter 114 e as the primary filter 114 e is rotated relative to the housing 40 e but also distributes the load that is exerted by the resilient filter gasket 780 over the entire width of the retaining tabs 776. Those skilled in the art will appreciate, however, that the lower surface 794 of the retaining tabs 776 need not be tapered, and that the retaining tabs 776 and retaining slots 790 could, in the alternative, be formed on the housing 40 e and the upper end cap 766, respectively.

With renewed reference to FIG. 15 and additional reference to FIG. 27, the hose assembly 18 e is preferably a flexible vacuum hose which may be removably coupled to either the inlet port 50 e or the outlet port 52 e. In the example provided, the hose assembly 18 e preferably includes a coupling end 850 with a tapered cylindrical body 852 and a pair of attachment lugs 854. The tapered cylindrical body 852 is constructed to be inserted into and frictionally engage a desired one of the inlet and outlet ports 50 e and 52 e. The attachment lugs 854 extend outwardly from the tapered cylindrical body 852 and are configured to be received into corresponding lug slots 860 formed in the walls of the inlet and outlet ports 50 e and 52 e. As best shown in FIGS. 15 and 16, each of the lug slots 860 may be L- or J-shaped having an insertion portion 864, which receives an associated one of the attachment lugs 854 when the coupling end 850 is axially inserted into the associated inlet or outlet port 50 e or 52 e, and a retaining portion 866, which extends around a portion of the inner circumference of the associated inlet or outlet port 50 e or 52 e. The terminal end 868 of the retaining portion 866 is somewhat elongated in a direction that is generally parallel to the insertion portion 864 so that when an attachment lug 854 is disposed therein and a force is applied to the hose assembly 18 e that tends to withdraw it from the powerhead assembly 12 e, the attachment lug 854 is able to move forwardly somewhat. As such, the exemplary coupling end 850 illustrated must be further inserted to the port and rotated to effect the uncoupling of the hose assembly 18 e from the powerhead assembly 12 e. The need to both further insert and rotate the coupling end 850 aids in resisting the uncoupling of the hose assembly 18 e from the port at an undesired time.

With reference to FIG. 14, the opposite end 880 of the hose assembly 18 e may be friction-finable to any of the hose-end attachments 20 e. Such hose-end attachments 20 e are well known in the art and as such, a detailed discussion of their construction and use need not be provided herein. To ensure that the hose-end attachments 20 e are secure and handy, the vacuum 10 e preferably includes a tool retainer 890 that may be integrally formed with the housing 40 e or discretely formed and coupled to the housing 40 e, as with screws (not shown).

In the example provided, the tool retainer 890 includes a pair of cylindrical recesses 900, which are configured to receive therein a crevice tool 20 e′ and a nozzle 20 e″, and a C-shaped collar 802 that is configured to frictionally engage (i.e., clamp about the perimeter of) the hose assembly 18 e. Accordingly, the user may store the hose assembly 18 e in a storage position as shown in FIG. 28 by inserting the coupling end 850 of the hose assembly 18 e to the inlet port 50 e, wrapping the hose assembly 18 e about a lateral side of the vacuum 10 e such that the hose assembly 18 e is captured below the battery enclosure 550 and lid 552 and clipping a portion of the hose assembly 18 e into the C-shaped collar 802. With the hose assembly 18 e thus stowed, the opposite end 880 of the hose assembly 18 e is maintained in a stationary position, which may have additional utility in situations where the vacuum 10 e is being operated to remove debris from an object and the user of the vacuum 10 e is using one hand to hold an object and the other hand to aid in clearing debris from the object. Stated another way, the C-shaped collar 802 may be used as a “third hand” to hold the opposite end 880 of the hose assembly 18 e as necessary. Preferably, the portion of the hose assembly,18 e between the C-Shaped collar 802 and the coupling end 850 (i.e., the body of the hose assembly 18 e) is in a state of tension (owing to the stretchy nature of the body of the hose assembly 18 e) so that the body of the hose assembly 18 e is secured to the housing 40 and canister 100 e when the hose assembly 18 e is placed in the storage position.

Alternatively, the coupling end 850 of the hose assembly 18 e may be inserted to one of the inlet and outlet ports 50 e and 52 e, the hose assembly 18 e wrapped about a lateral side of the vacuum 10 e such that the hose assembly 18 e is captured below the battery enclosure 550 and lid 552 and the opposite end 880 coupled to the other one of the inlet and outlet ports 50 e and 52 eas is illustrated in FIG. 29. Preferably, the portion of the hose assembly 18 e between the opposite end 880 and the coupling end 850 (i.e., the body of the hose assembly 18 e) is in a state of tension (owing to the stretchy nature of the body of the hose assembly 18 e) so that the body of the hose assembly 18 e is secured to the housing 40 and canister 100 e when the hose assembly 18 e is placed in this storage position.

Returning to FIG. 14, the shoulder strap 22 e may be coupled to the powerhead assembly 12 e to permit the user of the wet/dry vacuum 10 e to selectively wear the unit over their shoulder so that their hands may be used for other tasks, including transporting other equipment or manipulating the hose assembly 18 e when the wet/dry vacuum 10 e is in use. In the particular embodiment illustrated, the shoulder strap 22 e is coupled to the two clips 920 that extend from the housing 40 e in areas proximate the inlet and outlet ports 50 e and 52 e.

With additional reference to FIG. 30, an optional cord wrap 930 is also included with the vacuum 10 e. In the example provided, the cord wrap 930 comprises two L-shaped brackets 960 that are coupled to the housing 40 e. The brackets 960 include a large flange 962 that is spaced apart from the housing 40 e to define therebetween a cord-wrap cavity 964 about which the electrical cord 24 e may be wrapped for storage.

In FIG. 31, a tool set constructed in accordance with the teachings of the present disclosure is generally indicated by reference numeral 1000. The tool set 1000 includes various power tools 1002 and the above-described utility vacuum 10 e, which includes the battery pack 28 e. Each of the power tools 1002 are of a construction that includes a receptacle assembly 64 e with a configuration that is compatible and preferably similar or identical to the receptacle assembly 64 e of the utility vacuum 10 e to thereby permit the battery pack 28 e to be selectively coupled to a given one of the power tools 1002 to transmit electrical power thereto for the operation of the given power tool 1002. Advantageously, the battery pack 28 e may be selectively coupled to any of the components of the tool set 1000 to thereby power the selected power tool 1002 or the utility vacuum 10 e. While the particular power tools 1002 are illustrated to include a drill driver 1002 a, a circular saw 1002 b, a reciprocating saw 1002 c and a flashlight 1002 d, those skilled in the art will appreciate in light of this disclosure that the particular power tool may be of any desired type and may include, for example, hammer drills, jig saws, screw drivers, impact wrenches, rotary hammers, routers, spiral saws, plate joiners, metal working shears, grinders, sanders, buffers, self-leveling rotary lasers, manually-leveled rotary lasers and heavy-duty audio equipment.

While the disclosure has been described in the specification and illustrated in the drawings with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the disclosure as defined in the claims. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the disclosure without departing from the essential scope thereof. Therefore, it is intended that the disclosure not be limited to the particular embodiment illustrated by the drawings and described in the specification as the best mode presently contemplated for carrying out this disclosure, but that the disclosure will include any embodiments falling within the foregoing description and the appended claims. 

1. A tool set comprising: a battery pack; a power tool having a receptacle assembly for detachably receiving the battery pack; and a utility vacuum having a canister, a powerhead assembly and a shut-off device, the powerhead assembly being coupled to the canister and having a fan, a motor for providing rotary power to the fan, and a power supply for distributing electrical power to the motor, the fan including a fan inlet, the shut-off device being associated with the powerhead assembly and configured to prevent the fan from drawing a liquid into the fan inlet when a volume of the liquid in the canister exceeds a predetermined volume, the power supply including a receptacle assembly for detachably receiving the battery pack; wherein the battery pack may be selectively coupled to either of the power tool and the utility vacuum to provide a source of electrical power thereto.
 2. The tool set of claim 1, further comprising an electrical cord associated with the power supply, the electrical cord being configured to permit a user to selectively couple the power supply to a source of alternating current power.
 3. The tool set of claim 2, further comprising a battery charger, the battery charger being electrically coupled to one of the power supply and the electrical cord, the battery charger being operable for charging the battery pack when the electrical cord is coupled to the source of alternating current power.
 4. The tool set of claim 2, wherein the power supply includes a circuit for selecting between the source of alternating current power and electrical energy provided by the battery pack.
 5. The tool set of claim 4, wherein the circuit inhibits the battery pack from transmitting electrical power to the power supply when the power supply is receiving alternating current power.
 6. The tool set of claim 1, wherein the power tool is selected from a group of power tools consisting of flashlights, circular saws, reciprocating saws and drill drivers.
 7. The tool set of claim 1, further comprising a battery charger, the battery charger for recharging the battery pack.
 8. The tool set of claim 1, wherein the powerhead assembly includes a housing in which the fan, the motor and the power supply are housed, the housing including an inlet and an outlet, wherein operation of the utility vacuum draws an intake flow of air into the canister through the inlet and discharges a discharge flow of air through the outlet.
 9. The tool set of claim 8, wherein a cooling air intake aperture and a cooling air discharge aperture are formed in the housing, the cooling air discharge aperture being associated with the outlet so that air flowing through the outlet blows across the cooling air discharge aperture to set up a zone of relatively low pressure that causes air to be drawn out of the cooling air discharge aperture to thereby cool the motor.
 10. The tool set of claim 9, wherein the cooling air intake aperture is positioned proximate the inlet.
 11. The tool set of claim 10, wherein the cooling air intake aperture is positioned concentric about the inlet.
 12. The tool set of claim 1, further comprising a second battery pack that is interchangeable with the battery pack, the second battery pack having a voltage that is different than a voltage of the battery pack, the second battery pack being the source of direct current electrical power for powering the power supply when the second battery pack is interchanged with the battery pack and the power supply is not receiving alternating current power from the source of alternating current power. 